1. No category

Sound Light: photoacoustic
imaging of cancer
Wiendelt Steenbergen
MIRA institute / Biomedical Photonic Imaging Group
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Biomedical Photonic Imaging group
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Geography
Twente
Amsterdam
Enschede
(155000 inhabitants)
www.lib.utexas.edu/maps/europe/netherlands_rel87.jpg
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Enschede
1826
1916
2008
http://www.enschede-stad.nl
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2
Enschede
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Photoacoustic Imaging
p = Γμ a Φ ( x, y , z )
Absorption
Temperature
rise
Thermal
expansion
Stress
Sound
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3
Overview of tumor imaging studies
Animals:
• Vascularisation during tumor growth
Humans:
• PA Mammography
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Detection geometries
Wide angle detection
- Reconstruction needed
+ Can be made into array
Focussed detection
+ No reconstruction needed
- Cannot be made into array
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Photoacoustic imaging of subcutaneous tumor
• Lewis rat (male, 250 g)
• 8 x 106 pancreas tumor cells injected subcutaneously in hind
limb
• Measurements on day 3, 7, 8 and 10 (tumor injected on day 1)
• Wavelength 1064 nm
• Pulse duration 14 ns
• Pulse energy 2 mJ
• Focussed and unfocussed detector
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day 8
day 3
•
•
•
•
day 7
Lewis rat (male, 250 g)
Subcutaneous pancreas tumor
Wavelength 1064 nm
Focused detector
day 10
10
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Maximum intensity projections
0
x (mm)
5
10
15
0
y (mm)
unfocussed
sensor
5
10
15
day 3
day 7
day 8
day 10
focussed
sensor
Thumma et al., Optics Express (2005)
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Overview of tumor studies
Animals:
• Vascularisation during tumor growth
Humans:
• PA Mammography
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The Photoacoustic Mammoscope 1 (PAM1)
ultrasound detection array, 1 MHz
ND-YAG laser, 1064 nm, pulse energy 60 mJ
Phys. Med. Biol. (2005)
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panel 2
panel 1
panel 3
panel 4
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Photoacoustic mammography
pilot study
• Inclusion criteria
–
–
–
–
–
Palpable lump
X-ray and US: high suspicion for malignancy
Pre-selected by clinician for high probability of detection
Subjects in good general health (45 minutes exam)
Of legal age; fully competent to give informed consent etc
• Exclusion criteria
– Patients with history of surgical biopsies
Manohar et al., Optics Express (2007)
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Case
• 57 year, Caucasian
• Palpable lump central in
right breast
• Carcinoma with
neuroendocrine
differentiation
• ROI photoacoustic scan:
43x46 mm
• Breast thickness in
scanner: 59.5 mm
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Case 2 (#06166651)
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Optics Express (2007)
MIP image top view
Carcinoma
Pathology: tumor size = 26 mm
Photoacoustics: tumor size = 25 x 32 mm
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X-ray
Photoacoustics
Steps of ¼ mm,
from 20 to 5 mm depth
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Slices starting at 7 mm in steps of 1 mm
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Slices starting at 13 mm in steps of 1 mm
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Photoacoustics, current status
Capabilities of PA shown in vivo for
– Imaging of implanted subcutaneous tumors
• Resolution: 100-150 μm
• Measurement depth: 5 mm
– Breast imaging
• Instrumental resolution 3 mm
• Measurement depth 15-20 mm (128 averages)
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Needs for better photoacoustics
• faster imaging
– Parallel signal acquisition (money)
• more quantitative imaging
– More signals for better image reconstruction
– Cope with acoustic tissue inhomogeneities
– Measure absolute concentration of substances
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PAM2: from flat plate to tomography
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Needs for better photoacoustics
• faster imaging
– Parallel signal acquisition (money)
• more quantitative imaging
– More signals for better image reconstruction
– Cope with acoustic tissue inhomogeneities
– Measure absolute concentration of substances
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Imaging of acoustic parameters
Speed of sound and attenuation
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PVA inclusion in an agar phantom
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Effect of assumed speed of sound on PA image
Assumed SOS=1490 m/s
Using measured SoS map
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Effect of assumed speed of sound on PA image
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Water
1490 m/s
8 mm
3% agar
1494 m/s
Agar, milk,
indian ink
1508 m/s
0.23 Np/cm
5.5mm
PA Image
SOS
Attenuation
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Needs for better photoacoustics
• faster imaging
– Parallel signal acquisition (money)
• more quantitative imaging
– More signals for better image reconstruction
– Cope with acoustic tissue inhomogeneities
– Measure absolute concentration of substances
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Photoacoustic Imaging
p = Γμ a Φ ( x, y , z )
Absorption
Temperature
rise
Thermal
expansion
Stress
Sound
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Tissue …
is a pinball machine
BSc thesis H.E. van Herpt
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The quantification problem of photoacoustics
Initial pressure in absorbing volume after laser pulse:
Ρ0 = Γμ a Φ ( x, y, z ) ?
Γ: Grueneisen coefficient
Φ(x,y,z): Fluence
μa
Can we estimate absolute
absorption coefficients without
using a light transport model?
Yes
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Principle 2: labeling of light
acousto-optic modulation
ultrasound
source
tissue
light in
photon in
Δp, Δρ, Δn<0
Δp, Δρ, Δn>0
Labeled
photon
out
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Step 1: PA excitation in point 1 and 3
2
1
p12
p12 = Γμ a Φ12
μa
Φ12 = fluence
3
1
p23
2
p23 = Γμ a Φ 32
μa
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Step 2: label the light
inject in 1, label in 2, detect in 3
3
p13
L
2
1
μa
Amount of labeled light detected in 3:
1
3
p13
L ∝ Pr(1,2,3) ∝ Pr(1,2) Pr( 2,3) ∝ Pr(1,2) Pr(3,2) ∝ Φ 2 Φ 2
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Step 3: combining measurements
p12 = Γμ a Φ12
p23 = Γμ a Φ 32
p ∞Φ Φ
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L
1
2
3 equations, 3 unknowns
3
2
μa = c
p1 p3
p13
L
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Verification with Monte Carlo
20 mm
1
z
3
μ’s=0.4 mm-1
x
• 2D slab, thickness 20 mm
• Single absorbing inclusion: μa=0.025 , 0.05 and 0.1 mm-1
Position variations for the absorbing inclusion:
At fixed x=y=0: 4<z<16 mm
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Verification with Monte Carlo
varying z-position
-1
μa measured with Sound Light (mm )
#absorbed photons ∝ pressure=μaφ
Ρ0 = Γμ a Φ ( x, y, z )
0.01
1E-3
0.00 0.02 0.04 0.06 0.08 0.10 0.12
-1
Real μaof inclusion (mm )
0.12
0.10
Sound Light μa=real μa
0.08
0.06
0.04
0.02
0.00
0.00 0.02 0.04 0.06 0.08 0.10 0.12
-1
Real μa (mm )
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SOUND LIGHT: PRELIMINARY EXPERIMENTAL RESULTS
PA pressure P
PA pressure P
Abs 1
Abs 2
Abs 2
Abs 1
Abs 2
Abs 1
US-labeled light PL
μa1 ∝ P × P = 0.1092
1
a1
PL,a1
1
2
μa2 ∝ Pa2 × Pa2 = 0.1096
2
a1
1
PL,a 2
2
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SOUND LIGHT IN ONCOLOGY
PAM2, PAM3…
Research: quantification of
Clinical: mammography
• neovascularisation
• screening
• diagnosis
• monitoring of therapy
• smart contrast agents
• local drug delivery
• molecular processes
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Acknowledgments
University of Twente:
Srirang Manohar
Sanne Vaartjes
Erwin Hondebrink
Johan van Hespen
Jithin Jose
Kiran Kumar Thumma
Raja Gopal Rayavarapu
Roy Kolkman
Rene Kroes
Heike Faber
Gerbert ten Brinke
Khalid Daoudi
Alex Bratchenia
Rob Kooyman
Ton van Leeuwen
External:
Ronald Siphanto (Erasmus Medisch Centrum)
Han van Neck (Erasmus Medisch Centrum)
Joost Klaase (Medisch Spectrum Twente)
Frank van den Engh (Medisch Spectrum Twente)
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